Design and synthesis of new adamantyl-substituted antileishmanial ether phospholipids

A series of new 2-[3-(2-alkyloxy-ethyl)-adamantan-1-yl]-ethoxy substituted ether phospholipids was synthesized and their antileishmanial activity was evaluated against Leishmania infantum amastigotes. The majority of the new analogues were significantly less cytotoxic than miltefosine while, antiparasitic activity depended on the length of the 2-alkyloxy substituent. The most potent compounds were {2-[[[3-(2-hexyloxy-ethyl)-adamant-1-yl]-ethoxy]hydroxyphosphinyloxy]ethyl}-Ν,Ν,Ν-trimethyl-ammonium inner salt (5b) and {2-[[[3-(2-octyloxy-ethyl)-adamant-1-yl]-ethoxy]hydroxyphosphinyloxy]ethyl}-Ν,Ν,Ν-trimethyl-ammonium inner salt (5c).     

Phospholipase D-catalyzed synthesis of new phospholipids with polar head groups

A series of new phospholipids with polar head groups have been synthesized by enzymatic transphosphatidylation of 1,2-dioleoyl-sn-glycerophosphocholine and identified by 1H NMR and MALDI-TOF-MS. The acceptor alcohols were N- or C2-substituted derivatives of ethanolamine (diethanolamine, triethanolamine, serinol, Tris, BisTris). Phospholipases D from cabbage (PLDcab) and Streptomyces sp. (PLDStr) were compared with respect to product yield and purity as well as the initial rates in transphosphatidylation and competing hydrolysis. In all reactions, PLDStr showed a remarkably higher transphosphatidylation activity than PLDcab. However, higher yields of the phospholipids with diethanolamine, triethanolamine, and serinol were obtained by PLDcab because PLDStr resulted in the additional formation of diphosphatidyl derivatives. In the synthesis of the Tris and BisTris derivatives, PLD(Str) was much more appropriate because voluminous head group alcohols (>129A3) are poorly converted by PLDcab. With BisTris as acceptor alcohol two regioisomeric forms of phosphatidyl-BisTris were obtained.     

Dipentaerythritol in the Synthesis of New-Type Phospholipids

The first representatives of phospholipids of new types were synthesized on the basis of dipentaerythritol, 2,2′-[oxybis(methylen)]bis(hydroxymethyl))-1,3-propandiol. The starting polyol was phosphorylated with hexaethylphosphoric triamide to biphosphite, which was converted into thio- and selenophosphates by treatment with sulfur or selenium. The phosphoacetals were transformed into thio- and selenoanalogues of phospholipids by direct acylation with higher fatty acid chlorides.     

Chromatin phospholipids and DNA synthesis in hepatic cells

The synthesis of phospholipids found in microsomes, in the nuclei and in chromatin has been studied in rat liver after partial hepatectomy. [32P]O4(2-)incorporation in phospholipids has been compared with that of (3H) thymidine over a period of 48 h after operation. The presence of two peaks of DNA synthesis has been observed at 18 and 36 h; nuclear phospholipids show a continuous synthesis starting from 12 h, whereas the microsomes show two peaks at 12 and 24-30 h. The specific activity of the chromatin phospholipid fraction increases at 12h, doubles its initial value at 18 h, shows a peak at 30 h and comes back to the initial value at 48 h. It is concluded that chromatin phospholipids increase their synthesis in relation to the S phase of the cell cycle, whereas those of the nuclear membranes do not change the rate of synthesis throughout the cell cycle. The possibility is suggested that chromatin phospholipids are synthesized in the microsomes and transferred to the nucleus.     

The synthesis of phospholipids by direct amination

The bromoethylesters of phosphatidic acids and their analogues are general intermediates in the synthesis of phospholipids. A direct amination with different amines such as ammonia, methylamine, dimethylamine and trimethylamine results in the corresponding phosphatidylethanolamines and -cholines. In addition to the well elaborated reactions of bromoethylesters with trimethylamine and dimethylamine, the synthesis of phosphatidylethanolamines and -(N-methyl)-ethanolamines by amination with ammonia and methylamine is now possible in high yields (> 90%) without the need of the usual protecting groups.     

Parallel synthesis and antileishmanial activity of ether-linked phospholipids

The synthesis and antileishmanial activity of 18 edelfosine analogues are described. Compounds were obtained in parallel combining solid phase and solution phase synthesis. The most active analogue is characterized by the octadecyl group in position 2 of the glycerol chain. Considering that this substitution determines the loss of antitumor activity, a different mechanism of antileishmanial action can be hypothesized.     

Studies on the synthesis of liver phospholipids and the turnover of plasma phospholipids in non pregnant female rats using radioactive palmitate.

Using the tracer method and a compartmental model we found that 0.9 mumoles plasma free fatty acids per min are esterified to liver phospholipids. The turnover rate of plasma phospholipid fatty acids was determined to be 0.5 mumoles phospholipid fatty acids per min. The turnover time of the plasma phospholipid fatty acids was calculated to be 0.9 hours. The results indicate that only 69 per cent of plasma free fatty acids esterified to liver phospholipids are secreted by the liver into the plasma.     

Periodic synthesis of phospholipids during the Caulobacter crescentus cell cycle.

Net phospholipid synthesis is discontinuous during the Caulobacter crescentus cell cycle with synthesis restricted to two discrete periods. The first period of net phospholipid synthesis begins in the swarmer cell shortly after cell division and ends at about the time when DNA replication initiates. The second period of phospholipid synthesis begins at a time when DNA replication is about two-thirds complete and ends at about the same time that DNA replication terminates. Thus, considerable DNA replication, growth, and differentiation (stalk growth) occur in the absence of net phospholipid synthesis. In fact, when net phospholipid synthesis was inhibited by the antibiotic cerulenin through the entire cell cycle, both the initiation and the elongation phases of DNA synthesis occurred normally. An analysis of the kinetics of incorporation of radioactive phosphate into macromolecules showed that the periodicity of phospholipid synthesis could not have been detected by pulse-labeling techniques, and only an analysis of cells prelabeled to equilibrium allowed detection of the periodicity. Equilibrium-labeled cells also allowed determination of the absolute amount of phosphorus-containing macromolecules in newborn swarmer cells. These cells contain about as much DNA as one Escherichia coli chromosome and about four times as much RNA as DNA. The amount of phosphorus in phospholipids is about one-seventh of that in DNA, or about 3% of the total macromolecular phosphorus.     

Base-exchange reactions for the synthesis of phospholipids in nervous tissue: the incorporation of serine and ethanolamine into the phospholipids of isolated brain microsomes

Abstract— The calcium-dependent incorporation of l -[3-³H]serine and [1,2-¹⁴C]ethanol-amine into the phospholipid of isolated subcellular fractions from chick brain was studied and the properties of incorporation were examined. The microsomal fraction was found to possess the highest rate of incorporation and was able to convert under optimal conditions about 120 nmol of labelled serine and 220 nmol of ethanolamine/g of fresh brain microsomes/h. The requirement for Ca²⁺ ion appeared to be absolute. Mg²⁺ ion caused a gradual reduction in the existing enzymic activity, only when pre-incubated with microsomes and labelled bases before adding Ca²⁺ ion. The incorporation of serine and ethanolamine was actively inhibited by Hg²⁺, Co²⁺, Cu²⁺ and Mn²⁺ ions, and was abolished by ethylenediamine tetra-acetate treatment. Ethanolamine, but not choline, inositol or carnitine, competitively inhibited serine incorporation, while d -serine had slight effect. Conversely, l -serine inhibited competitively the incorporation of ethanolamine. The greater part of the incorporated serine (85 per cent) was localized in microsomal phosphatidylserine, while a small percentage was found in phosphatidylethanolamine. Similarly, 90 per cent of the incorporated ethanolamine was confined to phosphatidylethanolamine and a small percentage was found in the plasmalogen derivative. The mechanism of serine and ethanolamine incorporation was investigated. The results are compared with those published for similar mammalian and non-mammalian systems.     

Rapid degradation and limited synthesis of phospholipids in the cotyledons of mung bean seedlings

Seedling growth of mung bean is accompanied by the rapid catabolism of the three major phospholipids in the cotyledons (phosphatidylcholine, phosphatidylethanolamine, and phosphatidylinositol). The decline starts 24 hours after the beginning of imbibition and by the 4th day of growth more than 50% of the phospholipids have been catabolized. Extracts of cotyledons of 24-hour-imbibed beans contain enzymes capable of degrading membrane-associated phospholipids in vitro. This degradation involves phospholipase D and phosphatase activity.     

Involvement of phospholipids in polyunsaturated Fatty Acid synthesis in developing soybean cotyledons

Developing soybean (cv. Dare) cotyledons harvested at 30 days after flowering were pulse-labeled with [1-(14)C]oleoyl-CoA. The metabolic interrelation of radiolabeled unsaturated fatty acids between the major glycerolipid classes was determined at various time intervals. At chase time zero, [(14)C]oleic acid accounted for 99.2% of the total glycerolipid radioactivity, and phospholipids contained 92% of the total incorporated radioactivity. With time, phospholipids were metabolized in triacylglycerol biosynthesis and radioactivity was detected in polyunsaturated fatty acids. The hypothesis that phospholipids were metabolic intermediates in polyunsaturated fatty acid biosynthesis was tested by comparing the theoretical and the actual amount of radiolabeled oleic acid that was associated with triacylglycerol as a function of time. The radioactive oleic acid found in triacylglycerol at various intervals was derived from phospholipids via a diacylglycerol intermediate. Assuming no phospholipid desaturation, the potential or theoretical amounts of [(14)C]oleic acid that could be transferred to triacylglycerol from phospholipids was defined by a system of differential equations. The results demonstrated that the decline in [(14)C]oleic acid from phospholipid after long chase intervals was equal to the total amount of radioactive unsaturated fatty acids found in neutral lipids. The difference between the theoretical and actual amounts of [(14)C]oleic acid present in triacylglycerol after long time intervals was equal to the amount of radioactivity present in polyunsaturated fatty acids. Based upon those findings in soybeans, the desaturation of oleic acid associated with phospholipids was highly probable.     

Rapid synthesis and turnover of brain microsomal ether phospholipids in the adult rat.

The rates of synthesis, turnover, and half-lives were determined for brain microsomal ether phospholipids in the awake adult unanesthetized rat. A multicompartmental kinetic model of phospholipid metabolism, based on known pathways of synthesis, was applied to data generated by a 5 min intravenous infusion of [1,1-(3)H]hexadecanol. At 2 h post-infusion, 29%, 33%, and 31% of the total labeled brain phospholipid was found in the 1-O-alkyl-2-acyl-sn-glycero-3-phosphate, ethanolamine, and choline ether phospholipid fractions, respectively. Autoradiography and membrane fractionation showed that 3% of the net incorporated radiotracer was in myelin at 2 h, compared to 97% in gray matter microsomal and synaptosomal fractions. Based on evidence that ether phospholipid synthesis occurs in the microsomal membrane fraction, we calculated the synthesis rates of plasmanylcholine, plasmanylethanolamine, plasmenylethanolamine, and plasmenylcholine equal to 1.2, 9.3, 27.6, and 21.5 nmol. g(-1). min(-1), respectively. Therefore, 8% of the total brain ether phospholipids have half-lives of about 36.5, 26.7, 23.1, and 15.1 min, respectively. Furthermore, we clearly demonstrate that there are at least two pools of ether phospholipids in the adult rat brain. One is the static myelin pool with a slow rate of tracer incorporation and the other is a dynamic pool found in gray matter.The short half-lives of microsomal ether phospholipids and the rapid transfer to synaptosomes are consistent with evidence of the marked involvement of these lipids in brain signal transduction and synaptic function.     

Improved synthesis and pharmacologic activity of the enantiomers of a new benzofurane type antiarrhythmic compound

An improved synthesis of the enantiomers of the new benzofurane-type antiarrhythmic compound 1 is described, which makes use of the enantiomerically pure mbe-lactol. Thus, acylation of the benzofurane 4 with acetic anhydride and subsequent bromination gave the bromoacetyl-derivative 6 , which, after reduction with LiAlH₄, was protected with mbe-lactol to give a mixture of the diastereomers 8A and 8b . After separation via column chromatography assignment of absolute configuration was carried out using a well-established NMR- method. Reaction with propylamine and cleavage of the protective group gave (R)- 1 and (S)- 1 , respectively. Enantiomeric purity was confirmed using a direct HPLC method with rsp-cyclodextrine as stationary phase. Pharmacological investigations on isolated guinea pig heart muscle preparations showed that GE 68 and its two enantiomers did not significantly differ from each other with regard to their negative inotropic, negative chronotropic, and lack of β-adrenoceptor blocking action. In contrast, the reference drug propafenone was equally potent in its negative inotropic and chronotropic activity as GE 68, but additionally showed a weak β-adrenoceptor blocking activity. © 1994 Wiley-Liss, Inc.     

Construction of a lethal mutation in the synthesis of the major acidic phospholipids of Escherichia coli

In order to determine if the major acidic phospholipids of Escherichia coli are essential to the organism, we constructed a null allele (pgsA30) of the pgsA gene thus rendering the organism incapable of synthesizing phosphatidylglycerol or cardiolipin. In strains carrying the pgsA30 allele cell viability, synthesis of gene product and the ability to synthesize the two major acidic phospholipids were dependent on the presence of a functional copy of the pgsA gene carried on a plasmid which was temperature-sensitive for replication. Growth ceased at the temperature restrictive for plasmid replication when the acidic phospholipid content dropped to about 10% of wild type levels which is slightly higher than the level reported in cells carrying the pgsA3 allele in a genetic background derived from strain SD12; the latter cells, which are capable of synthesizing low levels of acidic phospholipids, were previously shown to have no abnormal growth phenotype (Miyazaki, C., Kuroda, M., Ohta, A., and Shibuya, I. (1985) Proc. Natl. Acad. Sci. U. S. A. 82, 7530-7534). The pgsA30 allele, unlike the pgsA3 allele, could not support growth in strain SD12. Neither allele could support growth in two other independently derived strains of E. coli. Therefore, there is a direct dependence of cell viability on a functional pgsA gene product. Strain SD12 appears to contain a suppressor which allows cells with a reduced capability to synthesize acidic phospholipid (pgsA3 allele) to grow, but cannot support growth in cells with a complete lack of synthetic capability (pgsA30 allele).